Workpiece surface detection method and system using the same

ABSTRACT

A detecting method for a workpiece surface includes the following steps. Firstly, a workpiece is provided with a first environment, wherein the first environment has a first environmental temperature higher than a first saturation temperature corresponding to an environmental-relative humidity. Then, the workpiece is provided with a second environment, wherein the second environment has a second environmental temperature lower than the first environmental temperature, such that a itself-temperature of the workpiece reduces to a mist temperature, wherein the mist temperature is substantially equal to or higher than the second environmental temperature. Then, the workpiece is provided with a mist environment, wherein the mist environment has a mist-saturation temperature corresponding to a mist-environmental relative humidity is equal to or higher than the mist temperature for misting a surface of the workpiece. Then, the surface of the misted workpiece is detected.

CROSS-REFERENCE TO RELATED APPLICATION

This is a divisional of U.S. application Ser. No. 15/392,325, filed Dec. 28, 2016, which claims the benefit of Taiwan application Serial No. 105135933, filed Nov. 4, 2016, the subject matter of which is incorporated herein by reference.

TECHNICAL FIELD

The technical field relates to a detecting method for a workpiece surface and a system using the same, and more particularly to a detecting method for the misted surface of a workpiece and a system using the same thereof.

BACKGROUND

In order to detect defects in a surface of a workpiece with high-reflectivity or to measure a size of the workpiece, a common method is to spray the surface of the workpiece with extinction powders for reducing the reflectivity. After the surface defects and the size are shown, the surface of the workpiece is inspected or measured by way of non-contact imaging technique. However, in such method, the extinction powders must be completely removed after inspecting and measuring, and thus it is very time-consuming and difficult, and easily leads to pollution of the production line. Accordingly, it is difficult to be widely used.

SUMMARY OF THE DISCLOSURE

According to an embodiment of the disclosure, a detecting method for a workpiece surface is provided. The detecting method includes the following steps. A workpiece is provided with a first environment, wherein the first environment has a first environmental temperature higher than a first saturation temperature corresponding to a first environmental relative humidity of the first environment; the workpiece is provided with a gas, wherein the gas has a gas-saturation temperature higher than a itself-temperature of the workpiece for misting a surface of the workpiece; and the surface of the misted workpiece is detected.

According to another embodiment of the disclosure, a detecting system for a workpiece surface is provided. The detecting system includes a first air-conditioning module, a gas provider and a detecting module. The first air-conditioning module is configured to provide a workpiece with a first environment, wherein the first environment has a first environmental temperature higher than a first saturation temperature corresponding to a first environmental relative humidity of the first environment. The gas provider is configured to provide the workpiece with a gas, wherein the gas has a gas-saturation temperature higher than an itself-temperature of the workpiece for misting a surface of the workpiece. The detecting module is configured to detect the surface of the misted workpiece.

The above and other aspects of the present disclosure will become better understood with regard to the following detailed description of the preferred but non-limiting embodiment (s). The following description is made with reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is schematic diagram showing a detecting system for a workpiece surface according to an embodiment of the present disclosure.

FIG. 2 is schematic diagram showing a flowchart of a detecting method for a workpiece surface according to an embodiment of the present disclosure.

FIG. 3 is schematic diagram showing a diagram of a temperature and humidity curve according to an embodiment of the present disclosure.

FIG. 4 is schematic diagram showing a curve of the measured reflectivity of the misted surface of the workpiece.

FIG. 5 is schematic diagram showing a diagram of a detecting system for a workpiece surface according to another embodiment of the present disclosure.

FIG. 6 is schematic diagram showing a flowchart of a detecting method for a workpiece surface according to another embodiment of the present disclosure.

FIG. 7 is schematic diagram showing a diagram of a temperature and humidity curve according to an embodiment of the present disclosure.

In the following detailed description, for purposes of explanation, numerous specific details are set forth in order to provide a thorough understanding of the disclosed embodiments. It will be apparent, however, that one or more embodiments may be practiced without these specific details. In other instances, well-known structures and devices are schematically shown in order to simplify the drawing.

DETAILED DESCRIPTION OF DISCLOSED EMBODIMENTS

FIG. 1 is schematic diagram showing a diagram of a detecting system 100 for a workpiece surface according to an embodiment of the present disclosure. The detecting system 100 includes a first air-conditioning module 110, a second air-conditioning module 120, a mist air-conditioning module 130, a detecting module 140 and a temperature sensor 150.

In the present embodiment, the first air-conditioning module 110, the second air-conditioning module 120 and the mist air-conditioning module 130 may separately provide the workpiece 10 with a first environment E1, a second environment E2 and a mist environment Ea for changing a temperature and a humidity of the workpiece 10, and misting a surface 10 s of the workpiece 10 by the mist environment Ea.

In the present embodiment, the first air-conditioning module 110, the second air-conditioning module 120 and the mist air-conditioning module 130 are disposed within or interconnect with a first space SP1, a second space SP2 and a mist space SP3 respectively for controlling the temperature and the humidity of these spaces. In another embodiment, the first air-conditioning module 110, the second air-conditioning module 120 and the mist air-conditioning module 130 may be disposed within the first space SP1, the second space SP2 and the mist space SP3 respectively. For example, the first space SP1, the second space SP2 and the mist space SP3 are three workstations in a production line or three different spaces in a laboratory.

In another embodiment, the first air-conditioning module 110, the second air-conditioning module 120 and the mist air-conditioning module 130 may be integrated into single air-conditioning module. In this embodiment, the first space SP1, the second space SP2 and the mist space SP3 may be the same space, wherein the single air-conditioning module may provide the same space with different temperature and the humidity at different timing. In addition, the first space SP1, the second space SP2 and/or the mist space SP3 may be a close space or an open space.

FIG. 2 is schematic diagram showing a flowchart of a detecting method for a workpiece surface according to an embodiment of the present disclosure.

In step S110, referring to FIGS. 1-3, FIG. 3 shows a diagram of a temperature and humidity curve according to an embodiment of the present disclosure. When the workpiece 10 is located at the first space SP1, the first air-conditioning module 110 provides the workpiece 10 with the first environment E1. The first air-conditioning module 110 includes a temperature controller and a humidity controller for controlling the temperature and the humidity of the first environment E1 at a first environmental temperature T_(e1) and a first environmental relative humidity H_(e1), wherein the first environmental temperature T_(e1) is higher than a first saturation temperature T_(s1) corresponding to the first environmental relative humidity H_(e1). As a result, it can prevent water droplet from being condensed on the surface 10 s of the workpiece 10. That is, due to the first environment E1 being a low humidity environment, it can prevent water droplet from being condensed on the surface 10 s of the workpiece 10.

In detail, as shown in FIG. 3, in the example of the first environmental temperature T_(e1) being 25° C., and the first environmental relative humidity H_(e1) being 30%, due to 25° C. being higher than the first saturation temperature T_(s1) corresponding to relative humidity 30%, that is, 6° C. (in horizontal dotted line toward left direction to correspond to 6° C.), the first environment E1 is at a lower humidity environment, such that it can prevent water droplet from being condensed on the surface 10 s of the workpiece 10. However, as long as water droplet is prevented from being condensed on the surface 10 s of the workpiece 10, the value of the first environmental temperature T_(e1) and the value of the first environmental relative humidity H_(e1), are not limited to the embodiment of the present disclosure.

In step S120, as shown in FIGS. 1 and 3, the workpiece 10 is moved to the second space S2, and the second air-conditioning module 120 provides the workpiece 10 with the second environment E2. The second air-conditioning module 120 may include a temperature controller and a humidity controller for controlling the temperature and the humidity of the second environment E2 at a second environmental temperature T_(e2), wherein the second environmental temperature T_(e2) is lower than the first environmental temperature T_(e1) for reducing a itself-temperature T_(b) to a mist temperature. In an embodiment, the mist temperature may be higher than the second environmental temperature T_(e2), or equal to or approaches the second environmental temperature T_(e2).

In step S130, whether the itself-temperature T_(b) of the workpiece 10 reaches the mist temperature is detected by the temperature sensor 150, whether the temperature sensor 150 is, for example, non-contact infrared sensor or other non-contact temperature sensor. If the itself-temperature T_(b) of the workpiece 10 reaches the mist temperature, the step S140 is performed; if not, the workpiece 10 may be maintained in the second environment E2 until the itself-temperature T_(b) of the workpiece 10 is reduced to the mist temperature. In another embodiment, if the itself-temperature T_(b) of the workpiece 10 has not reached to the mist temperature yet, the second air-conditioning module 120 may reduce the second environmental temperature T_(e2) to make the workpiece 10 reach to the mist temperature more fast. The aforementioned mist temperature may depend on the mist saturation temperature T_(sa) of the mist environment Ea; however, such exemplification is not meant to be for limiting.

In step S140, the mist air-conditioning module 130 provides the workpiece 10 with the mist environment Ea. The mist air-conditioning module 130 may include a temperature controller and a humidity controller for controlling the temperature and the humidity of the mist environment Ea at a mist-environmental relative humidity H_(ea) and a mist-environmental temperature T_(ea), wherein a mist-saturation temperature T_(sa) corresponding to the mist-environmental relative humidity H_(ea) is equal to or higher than the mist temperature for misting the surface 10 s of the workpiece 10.

As shown in FIG. 3, in the example of the mist temperature being 17° C., if the mist-environmental temperature T_(ea) is 25° C., the mist air-conditioning module 130 may humidify the mist environment Ea for increasing the mist-environmental relative humidity H_(ea) to 70% (as shown by point “a” in FIG. 3). As a result, the mist-saturation temperature T_(sa) corresponding to the relative humidity 70% is about 17° C., and accordingly the surface 10 s of the workpiece 10 may be misted. In another embodiment, the mist air-conditioning module 130 may humidify the mist environment Ea for increasing the mist-environmental relative humidity H_(ea) to be higher than 70%, for example, 80% (as shown by point “b” in FIG. 3). The mist-saturation temperature T_(sa) (about 21° C.) corresponding to the relative humidity 80% is higher than 17° C., and accordingly the surface 10 s of the workpiece 10 also may be misted. In addition, the aforementioned mist-environmental temperature T_(ea) may be higher than the mist temperature, and it is not limited to 25° C.

FIG. 4 is schematic diagram showing a curve of the reflectivity of the misted surface 10 s of the workpiece 10. When the workpiece 10 is a transparent acrylic material with low light transmittance, according to the measured results, the reflectivity of the surface 10 s of the workpiece 10 is less than 20% (as shown by the curve C11) before the surface 10 s of the workpiece 10 is misted, but is higher than 20% (as shown by curve C12) after the surface 10 s of the workpiece 10 is misted. When the workpiece 10 is a reflective sheet having a high light transmittance, according to the measured results, the reflectivity of the surface 10 s of the workpiece 10 is higher than 80% (as shown by the curve C21) before the surface 10 s of the workpiece 10 is misted, but is lower than 80% (as shown by curve C22) after the surface 10 s of the workpiece 10 is misted.

In step S150, the detecting module 140 inspects and/or measures the misted surface 10 s of the workpiece 10. For example, the detecting module 140 includes a robotic arm 141 and an optical detecting component 142, wherein the optical detecting component 142 is disposed on the robotic arm 141 for being driven by the robotic arm 141 to scan the three-dimensional contours of the surface 10 s of the workpiece 10 or inspect whether the surface 10 s has defects. In addition, the detecting module 140 may inspects and/or measures the workpiece 10 within or outside the mist space SP3.

FIG. 5 is schematic diagram showing a diagram of a detecting system 200 for a workpiece surface according to another embodiment of the present disclosure. The detecting system 200 includes the first air-conditioning module 110, a gas provider 220, the detecting module 140 and the temperature sensor 150. The present embodiment is different from above embodiment in that the gas provider 220 provides the workpiece 10 with mist environment.

FIG. 6 is schematic diagram showing a flowchart of an detecting method for a workpiece surface according to another embodiment of the present disclosure.

In step S210, and referring to FIG. 7, FIG. 7 is schematic diagram showing a diagram of a temperature and humidity curve according to another embodiment of the present disclosure. When the workpiece 10 is located at the first space SP1, the first air-conditioning module 110 provides the workpiece 10 with the first environment E1. For example, the first air-conditioning module 110 includes the temperature controller and the humidity controller for controlling the temperature and the humidity of the first environment E1 at the first environmental temperature T_(e1) and the first environmental relative humidity H_(e1) respectively, wherein the first environmental temperature T_(e1) is higher than the first saturation temperature T_(s1) corresponding to the first environmental relative humidity H_(e1). Due to the first environmental temperature T_(e1), the itself-temperature T_(b) of the workpiece 10 approaches the first environmental temperature T_(e1), wherein due to the first environmental temperature T_(e1) being higher than the first saturation temperature T_(s1) the itself-temperature T_(b) of the workpiece 10 is also higher than the first saturation temperature T_(s1). Since the itself-temperature T_(b) of the workpiece 10 is higher than the first saturation temperature T_(s1), water droplet is prevented from being condensed on the surface 10 s of the workpiece 10, and mist uniformity of the surface 10 s of the workpiece 10 will not be affected by water droplet. For example, as shown in FIG. 7, in the example of the first environmental temperature T_(e1) being 25° C. and the first environmental relative humidity H_(e1) being 40%, the first saturation temperature T_(s1) is 10° C. Thus, as long as the itself-temperature T_(b) of the workpiece 10 is higher than 10° C., it can prevent water droplet from being condensed on the surface 10 s of the workpiece 10. However, as long as water droplet is prevented from being condensed on the surface 10 s of the workpiece 10, the value of the first saturation temperature T_(s1) and value of the first environmental relative humidity H_(e1) are not limited to the present embodiment.

In addition, since the first environmental relative humidity H_(e1) may be controlled to be lower than the relative humidity outside the first environment E1, the first environment E1 is at a low humidity environment. As a result, even if there is water droplet at the surface 10 s of the workpiece 10, the water droplet will evaporate due to the low humidity environment.

In step S220, whether the itself-temperature T_(b) of the workpiece 10 is lower than the gas-saturation temperature T_(ga) of the gas 220 g (shown in FIG. 5) is detected by the temperature sensor 150, whether the temperature sensor 150 is, for example, non-contact infrared sensor or other non-contact temperature sensor. If the itself-temperature T_(b) of the workpiece 10 is lower than the gas-saturation temperature T_(ga), the step S230 is performed; if not, the workpiece 10 may be maintained in the first environment E1 until the itself-temperature T_(b) of the workpiece 10 is lower than the gas-saturation temperature T_(ga). Alternatively, the itself-temperature T_(b) of the workpiece 10 may be much rapidly reduced to be lower than the gas-saturation temperature T_(ga) of the gas 220 g by way of reducing the first environmental temperature T_(e1).

In step S230, the gas provider 220 provides the workpiece 10 with the mist environment Ea. For example, the gas provider 220 provides the workpiece 10 with the aforementioned gas 220 g. The gas 220 g is, for example, vapor or mixture of vapor and gas. The gas provider 220 is, for example, an evaporator, sprayer, or other gas provider capable of providing various temperatures and/or relative humidity. In the example of the relative humidity H_(eg) of the gas 220 g being 100%, as shown in FIG. 7, due to the gas-saturation temperature T_(gs) is equal to or higher than the itself-temperature T_(b) of the workpiece 10, the surface 10 s of the workpiece 10 may be misted. For example, in the example of the gas-saturation temperature T_(gs) of the gas 220 g being 32° C., since 32° C. is higher than the itself-temperature T_(b) of the workpiece 10 which is 25° C., for example, and accordingly the surface 10 s of the workpiece 10 may be misted. In detail, the gas-saturation temperature T_(gs) of the gas 220 g is higher than the itself-temperature T_(b) of the workpiece 10, and accordingly the gas 220 g will be condensed on the surface 10 s of the workpiece 10 when being contacting with the surface 10 s. In addition, the gas 220 g may include several fine water droplets each having a diameter of 0.1 micrometers to 2 micrometers, such that the surface 10 s forms a misted surface.

In step S240, the detecting module 140 inspects and/or measures the misted surface 10 s of the workpiece 10. For example, the detecting module 140 includes the robotic arm 141 and the optical detecting component 142 disposed on the robotic arm 141 for being driven by the robotic arm 141 to scan the three-dimensional contours of the surface 10 s of the workpiece 10 or inspect whether the surface 10 s has defects. In addition, the detecting module 140 may inspects and/or measures the workpiece 10 within or outside the mist space SP3.

As described above, an detecting method of an embodiment of the present disclosure provides a dry process (for example, the aforementioned first environment), a cooling process (for example, the aforementioned second environment) and a humidifying and misting process (for example, the aforementioned mist environment), wherein the fine water droplet (misted) is condensed on the surface of the workpiece in the last humidifying and misting process. In another embodiment, a detecting method provides a dry process (for example, the aforementioned first environment) and a gas, wherein the gas-saturation temperature of the gas is higher than a itself-temperature of the workpiece, such that the surface of the workpiece is misted when the gas contacts the surface of the workpiece having relative low temperature and then is condensed.

It will be apparent to those skilled in the art that various modifications and variations can be made to the structure of the disclosed embodiments without departing from the scope or spirit of the disclosure. In view of the foregoing, it is intended that the disclosure cover modifications and variations of the present disclosure provided they fall within the scope of the following claims and their equivalents. 

What is claimed is:
 1. A detecting method for a workpiece surface, comprising: providing a workpiece with a first environment, wherein the first environment has a first environmental temperature higher than a first saturation temperature corresponding to a first environmental-relative humidity of the first environment; providing the workpiece with a gas, wherein the gas has a gas-saturation temperature higher than a itself-temperature of the workpiece for misting a surface of the workpiece; and detecting the surface of the misted workpiece.
 2. The detecting method according to claim 1, wherein the surface of the misted workpiece is detected by way of non-contact.
 3. The detecting method according to claim 1, wherein the step of providing the workpiece with the first environment is completed in a first space; after the step of providing the workpiece with the first environment, the detecting method further comprises: transporting the workpiece to a mist space for performing the step of providing the workpiece with the gas.
 4. The detecting method according to claim 1, wherein the step of providing the workpiece with the first environment and the step of providing the workpiece with the gas are completed in the same space.
 5. A detecting system for a workpiece surface, comprising: a first air-conditioning module configured to provide a workpiece with a first environment, wherein the first environment has a first environmental temperature higher than a first saturation temperature corresponding to a first environmental relative humidity of the first environment; a gas provider configured to provide the workpiece with a gas, wherein the gas has a gas-saturation temperature higher than a itself-temperature of the workpiece for misting a surface of the workpiece; and a detecting module configured to detect the surface of the misted workpiece.
 6. The detecting system according to claim 5, further comprising: a temperature sensor configured to detect whether the itself-temperature of the workpiece is lower than the gas-saturation temperature.
 7. The detecting system according to claim 5, wherein the first air-conditioning module and the gas provider are disposed within a first space and a mist space respectively, and the first space and the mist space are different spaces.
 8. The detecting system according to claim 5, wherein the first air-conditioning module and the gas provider are located at the same space. 